Progressive addition lenses are lenses that gradually change in optical power from the top to the bottom to provide clear vision at all distances without visible lines. They were invented in 1907 and the Varilux 1 was introduced in 1959. Unlike bifocals or trifocals, progressives ensure smooth vision at all distances. The power increase is achieved by gradually decreasing the lens curvature vertically and horizontally. Progressives have advantages over other lenses like continuous vision and no visible lines. Optical design factors like add power, corridor length, and zone widths affect progressives. Proper fitting involves adjusting the frame position and measuring pupil distance and fitting height.
2. Progressive Addition Lenses
The concept of progressive addition lens has
been around since 1907 when the first patent
on progressive power lens was published by
Owen Ave.
Varilux 1 was introduced by Essilor in France
in the year 1959.
3. Progressive addition lenses are one piece
lenses that vary gradually in surface curvature
from a minimum value in the upper distance
portion to a maximum value in the lower near
portion.
4. Unlike bifocal or trifocal lenses, progressive
lenses ensure that the presbyopic spectacle
wearer finds the right dioptric power for every
distance, guaranteeing smooth and uninterrupted
vision without any visible line of demarcation
5. The power increase is achieved by constantly
decreasing the radii of curvature in the vertical
and horizontal directions.
7. Distance
A designated zones located in the upper portion
of the lens, which provides the necessary
distance correction.
Near
A designated zone in the lower portion of the
lens, which provides the necessary near
addition or near power.
8. Intermediate
A corridor in the central portion of the lens
connects these two zones, which increases
progressively in plus power from the distance
to near. This zone is also known as
“progressive zone”.
9. BASIC DESIGN DIFFERENCE BETWEEN
PROGRESSIVE, SINGLE VISION, BIFOCAL
AND TRIFOCAL LENSES
Basic design principle of single vision lens
12. ADVANTAGES OF PROGRESSIVE
ADDITION LENSES
No Visible Segments
No line of demarcation provides more
cosmetically appealing lenses with continuous
vision, free from visually distracting borders.
The lens looks like a single vision lens.
16. Add Power
The amount of astigmatism will be directly
proportional to the add power of the lens.
A + 2.00D addition, for example, will
generally produce twice as much cylinder error
as + 1.00 D addition.
17. Length of the Progressive Corridor
Width of Distance and Near Zone
19. Mono Design and Multidesign
In case of mono design progressive addition
lens, a single design is used for all addition
powers.
The position for the near vision does not
change with the change in near addition power
causing difficulties while viewing near objects
as the wearer holds reading material closer to
him with the increase in his near addition
power.
20. In multi design the position for near vision
changes with the addition power change, i.e.,
the near area goes up with the increase in the
addition.
21. Asymmetry and Symmetry Design
In case of symmetrical progressive addition
lens design, the right and the left lenses are
identical.
Asymmetric progressive addition lens design
incorporates a nasal offset of the near zone and
has separate design for right and left lens.
22. Hard and Soft Design
A harder progressive addition lens design
concentrates the astigmatic error into smaller areas of
the lens surface, thereby expanding the areas of
perfectly clear vision at the expense of higher levels
of blur and distortion.
1.Wider distance zones
2. Wider near zones
3. More narrow and shorter progressive corridors
4. More rapidly increasing levels of astigmatic error
23. Soft Design
A softer progressive addition lens design spreads
the astigmatic error across larger areas of the
surface, thereby reducing the overall magnitude of
blur at the expense of narrowing the zones of
perfectly clear vision.
1.Narrower distance zones
2. Narrower near zones
3. Longer and wider progressive corridors
4. More slowly increasing levels of astigmatic
error.
26. A and A1: They are two hidden circles,
which are permanently etched on the lens at
34 mm apart.
B: This point is the distance optical centre
(DOC) of the lens and is also known as
Prism Reference Point.
27. C: Hidden addition power situated at the
temporal side and is made visible by fogging.
D: 0-180° axis line passing through the DOC.
E: Fitting cross lies above the DOC.
28. F: This is the Distance Power (DP) circle to
check the exact distance power with the help
of lensometer.
G: Hidden logo situated nasally and is made
visible by fogging when the ink marking is
removed.
H: 7mm to 9 mm circle is the centre of the near
vision area and is inset by 2.5 mm.
33. Vertex Distance
Minimize Vertex distance by adjusting
nose pads but avoid contacting the
eyelashes with the lens
34. Once the above adjustment are done, take
the following two measurement:
1. Monocular PD for distance
2. The fitting height
35. Fitting HeigHt
The fitting cross on progressive addition
lens must coincide with the pupil centre of
the wearers in their natural posture.
36. The following procedure is used to
measure the fitting height:-
Place your self opposite and at the same height
as the wearer.
Ask the wearer to adopt a comfortable posture
and look straight ahead.
Ask the wearer to look at your LE.
Hold a pen torch just below your LE.
37.
38. Close your RE to avoid parallax error.
Observe the position of the light reflection in
the wearers RE relative to the vertical PD line
already marked on the lens.
Place a small horizontal mark on the PD line
corresponding to the pupil centre.
39.
40. Ask the wearer to look at your RE and
complete the procedure for the other eye.
Move the frame up and down slightly, let it
settle, and report for both eyes.
Confirm the final marked lens insert
41. The ideal position of the fitting cross should
be as shown